Isolation and characterisation of the cDNA encoding a glycosylated accessory protein of pea chloroplast DNA polymerase.

The cDNA encoding p43, a DNA binding protein from pea chloroplasts (ct) that binds to cognate DNA polymerase and stimulates the polymerase activity, has been cloned and characterised. The characteristic sequence motifs of hydroxyproline-rich glyco-proteins (HRGP) are present in the cDNA corres-ponding to the N-terminal domain of the mature p43. The protein was found to be highly O-arabinosylated. Chemically deglycosylated p43 (i.e. p29) retains its binding to both DNA and pea ct-DNA polymerase but fails to stimulate the DNA polymerase activity. The mature p43 is synthesised as a pre-p43 protein containing a 59 amino acid long transit peptide which undergoes stromal cleavage as evidenced from the post-translational in vitro import of the precursor protein into the isolated intact pea chloroplasts. Surprisingly, p43 is found only in pea chloroplasts. The unique features present in the cloned cDNA indicate that p43 is a novel member of the HRGP family of proteins. Besides p43, no other DNA-polymerase accessory protein with O-glycosylation has been reported yet.     

A 43 kDa DNA binding protein from the pea chloroplast interacts with and stimulates the cognate DNA polymerase.

A DNA binding protein with DNA polymerase 'accessory activity' has been identified and purified to apparent homogeneity from pea chloroplasts. This protein consists of a single subunit of 43 kDa and binds to DNA regardless of its base sequence and topology. It increases cognate DNA polymerase-primase activity in a dose dependent manner. Using solid phase protein-protein interaction trapping and co-immunoprecipitation techniques, the purified protein was found to associate with the chloroplast DNA polymerase. The chloroplast DNA polymerase also binds directly to the radioiodinated 43 kDa protein. The specific interaction between 43 kDa protein and chloroplast DNA polymerase results in the synthesis of longer DNA chains. The 43 kDa protein, present abundantly in the pea chloroplast, appears to increase processivity of the chloroplast DNA polymerase and may play an important role in the replication of pea chloroplast DNA.     

A 70-kDa chloroplast DNA polymerase from pea (<Emphasis Type="Italic">Pisum sativum</Emphasis>) that shows high processivity and displays moderate fidelity

A 70-kDa chloroplast (ct) DNA polymerase from pea has been purified to apparent homogeneity. The ct DNA polymerase was insensitive to dideoxynucleotides (d(2) NTP) but showed high sensitivity to phosphonoacetic acid. The enzyme lacked any detectable 5'-->3' exonuclease activity but showed 3'-->5' exonuclease activity. The polymerase displayed high processivity (3 kb) and moderate fidelity, which may be sufficient for the faithful replication of the 140-kb pea ct genome. A 43-kDa accessory protein increased the polymerization rate but did not affect the rate of mis-incorporation in vitro, thus indicating that the domains for polymerisation and proof reading may be spatially separate.     

The mitochondrial p55 accessory subunit of human DNA polymerase gamma enhances DNA binding, promotes processive DNA synthesis, and confers N-ethylmaleimide resistance

Human DNA polymerase gamma is composed of a 140-kDa catalytic subunit and a smaller accessory protein variously reported to be 43-54 kDa. Immunoblot analysis of the purified, heterodimeric native human polymerase gamma complex identified the accessory subunit as 55 kDa. We isolated the full-length cDNA encoding a 55-kDa polypeptide, expressed the cDNA in Escherichia coli and purified the 55-kDa protein to homogeneity. Recombinant Hp55 forms a high affinity, salt-stable complex with Hp140 during protein affinity chromatography. Immunoprecipitation, gel filtration, and sedimentation analyses revealed a 190-kDa complex indicative of a native heterodimer. Reconstitution of Hp140.Hp55 raises the salt optimum of Hp140, stimulates the polymerase and exonuclease activities, and increases the processivity of the enzyme by several 100-fold. Similar to Hp140, isolated Hp55 binds DNA with moderate strength and was a specificity for double-stranded primer-template DNA. However, Hp140.Hp55 has a surprisingly high affinity for DNA, and kinetic analyses indicate Hp55 enhances the affinity of Hp140 for primer termini by 2 orders of magnitude. Thus the enhanced DNA binding caused by Hp55 is the basis for the salt tolerance and high processivity characteristic of DNA polymerase gamma. Observation of native DNA polymerase gamma both as an Hp140 monomer and as a heterodimer with Hp55 supports the notion that the two forms act in mitochondrial DNA repair and replication. Additionally, association of Hp55 with Hp140 protects the polymerase from inhibition by N-ethylmaleimide.     

DNA footprinting studies of the complex formed by the T4 DNA polymerase holoenzyme at a primer-template junction

We have used DNA footprinting techniques to analyze the interactions of five DNA replication proteins at a primer-template junction: the bacteriophage T4 DNA polymerase (the gene 43 protein), its three accessory proteins (the gene 44/62 and 45 proteins), and the gene 32 protein, which is the T4 helix-destabilizing (or single-stranded DNA-binding) protein. The 177-nucleotide-long DNA substrate consisted of a perfect 52-base pair hairpin helix with a protruding single-stranded 5' tail. As expected, the DNA polymerase binds near the 3' end of this molecule (at the primer-template junction) and protects the adjacent double-stranded region from cleavage. When the gene 32 protein binds to the single-stranded tail, it reduces the concentration of the DNA polymerase required to observe the polymerase footprint by 10-30-fold. Periodic ATP hydrolysis by the 44/62 protein is required to maintain the activity of the DNA polymerase holoenzyme (a complex of the 43, 44/62, and 45 proteins). Footprinting experiments demonstrate the formation of a weak complex between the DNA polymerase and the gene 45 protein, but there is no effect of the 44/62 protein or ATP on this enlarged footprint. We propose a model for holoenzyme function in which the complex of the three accessory proteins uses ATP hydrolysis to keep a moving polymerase tightly bound to the growing 3' end, providing a "clock" to measure polymerase stalling.     

Stimulation of human DNA polymerase epsilon by MDM2

The human DNA polymerase ε catalytic subunit consists of a 140-kDa N‐terminal domain that contains the catalytic activity and a 120-kDa C-terminal domain that binds to the other subunits and to exogenous peptides, including PCNA and MDM2. We report here that recombinant human MDM2 purified from insect cells or Escherichia coli stimulated the activity of DNA polymerase ε up to 10- and 40-fold, respectively, but not those of DNA polymerase β or Klenow fragment of E.coli DNA polymerase I. Kinetic studies indicated that MDM2 increased the maximum velocity of the reaction, but did not change substrate affinities. The stimulation depended upon the interaction of the N‐terminal 166 amino acid residues of MDM2 with the C-terminal domain of the full-length catalytic subunit, since the deletion of 166 amino acids from N‐terminal of MDM2 or the removal of the C-terminal domain of DNA polymerase ε by trypsin digestion or competition for binding to it by the addition of excess C-terminal fragment eliminated the stimulation. Since DNA polymerase ε appears to be involved in DNA replication, recombination and repair synthesis, we suggest that MDM2 binding to DNA polymerase ε might be part of a reconfiguration process that allows DNA polymerase ε to associate with repair/recombination proteins in response to DNA damage.     

Primer utilization by DNA polymerase alpha-primase is influenced by its interaction with Mcm10p

Models of DNA replication in yeast and Xenopus suggest that Mcm10p is required to generate the pre-initiation complex as well as progression of the replication fork during the elongation of DNA chains. In this report, we show that the Schizosaccharomyces pombe Mcm10p/Cdc23p binds to the S. pombe DNA polymerase (pol) alpha-primase complex in vitro by interacting specifically with the catalytic p180 subunit and stimulates DNA synthesis catalyzed by the pol alpha-primase complex with various primed DNA templates. We investigated the mechanism by which Mcm10p activates the polymerase activity of the pol alpha-primase complex by generating truncated derivatives of the full-length 593-amino acid Mcm10p. Their ability to stimulate pol alpha polymerase activity and bind to single-stranded DNA and to pol alpha were compared. Concomitant with increased deletion of the N-terminal region (from amino acids 95 to 415), Mcm10p derivatives lost their ability to stimulate pol alpha polymerase activity and bind to single-stranded DNA. Truncated derivatives of Mcm10p containing amino acids 1-416 retained the pol alpha binding activity, whereas the C terminus, amino acids 496-593, did not. These results demonstrate that both the single-stranded DNA binding and the pol alpha binding properties of Mcm10p play important roles in the activation. In accord with these findings, Mcm10p facilitated the binding of pol alpha-primase complex to primed DNA and formed a stable complex with pol alpha-primase on primed templates. A mutant that failed to activate or bind to DNA and pol alpha, was not observed in this complex. We suggest that the interaction of Mcm10p with the pol alpha-primase complex, its binding to single-stranded DNA, and its activation of the polymerase complex together contribute to its role in the elongation phase of DNA replication.     

Tobacco proliferating cell nuclear antigen binds directly and stimulates both activity and processivity of ddNTP-sensitive mungbean DNA polymerase

PCNA is well known as a component of DNA replication system and plays important roles in multiple cellular pathways in addition to replication and repair. In this work we have demonstrated the physical and functional interaction between tobacco PCNA and mungbean ddNTP-sensitive DNA polymerase which shares many physicochemical properties with family X-DNA polymerases except with the moderately processive mode of nucleotide incorporation. We have shown here that recombinant PCNA binds directly to mungbean DNA polymerase as revealed in affinity chromatography, pull-down and co-immunoprecipitation approaches. In vitro DNA polymerase activity assay and processivity analyses indicated recombinant PCNA specifically stimulates both activity and processivity of mungbean DNA polymerase. These observations lead to interesting speculation about the functional significance of the ddNTP-sensitive enzyme in replication event in higher plants since the enzyme has been shown to be active and expressed at an elevated level during the endoreduplication stages in developing mungbean seeds.     

PolDIP2 interacts with human PrimPol and enhances its DNA polymerase activities

Translesion synthesis (TLS) employs specialized DNA polymerases to bypass replication fork stalling lesions. PrimPol was recently identified as a TLS primase and polymerase involved in DNA damage tolerance. Here, we identify a novel PrimPol binding partner, PolDIP2, and describe how it regulates PrimPol''s enzymatic activities. PolDIP2 stimulates the polymerase activity of PrimPol, enhancing both its capacity to bind DNA and the processivity of the catalytic domain. In addition, PolDIP2 stimulates both the efficiency and error-free bypass of 8-oxo-7,8-dihydrodeoxyguanosine (8-oxoG) lesions by PrimPol. We show that PolDIP2 binds to PrimPol''s catalytic domain and identify potential binding sites. Finally, we demonstrate that depletion of PolDIP2 in human cells causes a decrease in replication fork rates, similar to that observed in PrimPol^−/− cells. However, depletion of PolDIP2 in PrimPol^−/− cells does not produce a further decrease in replication fork rates. Together, these findings establish that PolDIP2 can regulate the TLS polymerase and primer extension activities of PrimPol, further enhancing our understanding of the roles of PolDIP2 and PrimPol in eukaryotic DNA damage tolerance.     

Functional interactions of mitochondrial DNA polymerase and single-stranded DNA-binding protein. Template-primer DNA binding and initiation and elongation of DNA strand synthesis.

Functional interactions between mitochondrial DNA polymerase (pol gamma) and mitochondrial single-stranded DNA-binding protein (mtSSB) from Drosophila embryos have been evaluated with regard to the overall activity of pol gamma and in partial reactions involving template-primer binding and initiation and idling in DNA strand synthesis. Both the 5' --> 3' DNA polymerase and 3' --> 5' exonuclease in pol gamma are stimulated 15-20-fold on oligonucleotide-primed single-stranded DNA by native and recombinant forms of mtSSB. That the extent of stimulation is similar for both enzyme activities over a broad range of KCl concentrations suggests their functional coordination and a similar mechanism of stimulation by mtSSB. At the same time, the high mispair specificity of pol gamma in exonucleolytic hydrolysis is maintained, indicating that enhancement of pol gamma catalytic efficiency is likely not accompanied by increased nucleotide turnover. DNase I footprinting of pol gamma.DNA complexes and initial rate measurements show that mtSSB enhances primer recognition and binding and stimulates 30-fold the rate of initiation of DNA strands. Dissociation studies show that productive complexes of the native pol gamma heterodimer with template-primer DNA are formed and remain stable in the absence of replication accessory proteins.     

A novel processive mechanism for DNA synthesis revealed by structure, modeling and mutagenesis of the accessory subunit of human mitochondrial DNA polymerase

Mitochondrial DNA polymerase (pol gamma) is the sole DNA polymerase responsible for replication and repair of animal mitochondrial DNA. Here, we address the molecular mechanism by which the human holoenzyme achieves high processivity in nucleotide polymerization. We have determined the crystal structure of human pol gamma-beta, the accessory subunit that binds with high affinity to the catalytic core, pol gamma-alpha, to stimulate its activity and enhance holoenzyme processivity. We find that human pol gamma-beta shares a high level of structural similarity to class IIa aminoacyl tRNA synthetases, and forms a dimer in the crystal. A human pol gamma/DNA complex model was developed using the structures of the pol gamma-beta dimer and the bacteriophage T7 DNA polymerase ternary complex, which suggests multiple regions of subunit interaction between pol gamma-beta and the human catalytic core that allow it to encircle the newly synthesized double-stranded DNA, and thereby enhance DNA binding affinity and holoenzyme processivity. Biochemical properties of a novel set of human pol gamma-beta mutants are explained by and test the model, and elucidate the role of the accessory subunit as a novel type of processivity factor in stimulating pol gamma activity and in enhancing processivity.     

GINS is a DNA polymerase epsilon accessory factor during chromosomal DNA replication in budding yeast

GINS is a protein complex found in eukaryotic cells that is composed of Sld5p, Psf1p, Psf2p, and Psf3p. GINS polypeptides are highly conserved in eukaryotes, and the GINS complex is required for chromosomal DNA replication in yeasts and Xenopus egg. This study reports purification and biochemical characterization of GINS from Saccharomyces cerevisiae. The results presented here demonstrate that GINS forms a 1:1 complex with DNA polymerase epsilon (Pol epsilon) holoenzyme and greatly stimulates its catalytic activity in vitro. In the presence of GINS, Pol epsilon is more processive and dissociates more readily from replicated DNA, while under identical conditions, proliferating cell nuclear antigen slightly stimulates Pol epsilon in vitro. These results strongly suggest that GINS is a Pol epsilon accessory protein during chromosomal DNA replication in budding yeast. Based on these results, we propose a model for molecular dynamics at eukaryotic chromosomal replication fork.     

Pea chloroplast DNA primase: characterization and role in initiation of replication

A DNA primase activity was isolated from pea chloroplasts and examined for its role in replication. The DNA primase activity was separated from the majority of the chloroplast RNA polymerase activity by linear salt gradient elution from a DEAE-cellulose column, and the two enzyme activities were separately purified through heparin-Sepharose columns. The primase activity was not inhibited by tagetitoxin, a specific inhibitor of chloroplast RNA polymerase, or by polyclonal antibodies prepared against purified pea chloroplast RNA polymerase, while the RNA polymerase activity was inhibited completely by either tagetitoxin or the polyclonal antibodies. The DNA primase activity was capable of priming DNA replication on single-stranded templates including poly(dT), poly(dC), M13mp19, and M13mp19_+ 2.1, which contains the AT-rich pea chloroplast origin of replication. The RNA polymerase fraction was incapable of supporting incorporation of ³H-TTP in in vitro replication reactions using any of these single-stranded DNA templates. Glycerol gradient analysis indicated that the pea chloroplast DNA primase (115–120 kDa) separated from the pea chloroplast DNA polymerase (90 kDa), but is much smaller than chloroplast RNA polymerase. Because of these differences in size, template specificity, sensitivity to inhibitors, and elution characteristics, it is clear that the pea chloroplast DNA primase is an distinct enzyme form RNA polymerase. In vitro replication activity using the DNA primase fraction required all four rNTPs for optimum activity. The chloroplast DNA primase was capable of priming DNA replication activity on any single-stranded M13 template, but shows a strong preference for M13mp19+2.1. Primers synthesized using M13mp19+2.1 are resistant to DNase I, and range in size from 4 to about 60 nucleotides.     

Yeast mitochondrial DNA polymerase is a highly processive single-subunit enzyme

Polymerase γ is solely responsible for fast and faithful replication of the mitochondrial genome. High processivity of the polymerase γ is often achieved by association of the catalytic subunit with accessory factors that enhance its catalytic activity and/or DNA binding. Here we characterize the intrinsic catalytic activity and processivity of the recombinant catalytic subunit of yeast polymerase γ, the Mip1 protein. We demonstrate that Mip1 can efficiently synthesize DNA stretches of up to several thousand nucleotides without dissociation from the template. Furthermore, we show that Mip1 can perform DNA synthesis on double-stranded templates utilizing a strand displacement mechanism. Our observations confirm that in contrast to its homologues in other organisms, Mip1 can function as a single-subunit replicative polymerase.     

The Leu22Pro tumor-associated variant of DNA polymerase beta is dRP lyase deficient

Approximately 30% of human tumors characterized to date express DNA polymerase beta (pol β) variant proteins. Two of the polymerase beta cancer-associated variants are sequence-specific mutators, and one of them binds to DNA but has no polymerase activity. The Leu22Pro (L22P) DNA polymerase beta variant was identified in a gastric carcinoma. Leu22 resides within the 8 kDa amino terminal domain of DNA polymerase beta, which exhibits dRP lyase activity. This domain catalyzes the removal of deoxyribose phosphate during short patch base excision repair. We show that this cancer-associated variant has very little dRP lyase activity but retains its polymerase activity. Although residue 22 has no direct contact with the DNA, we report here that the L22P variant has reduced DNA-binding affinity. The L22P variant protein is deficient in base excision repair. Molecular dynamics calculations suggest that alteration of Leu22 to Pro changes the local packing, the loop connecting helices 1 and 2 and the overall juxtaposition of the helices within the N-terminal domain. This in turn affects the shape of the binding pocket that is required for efficient dRP lyase catalysis.     

Autogenous translational operator recognized by bacteriophage T4 DNA polymerase

The synthesis of the DNA polymerase of bacteriophage T4 is autogenously regulated. This protein (gp43), the product of gene 43, binds to a segment of its mRNA that overlaps its ribosome binding site, and thereby blocks translation. We have determined the Kd of the gp43-operator interaction to be 1.0 x 10(-9) M. The minimum operator sequence to which gp43 binds consists of 36 nucleotides that include a hairpin (containing a 5 base-pair helix and an 8 nucleotide loop) and a single-stranded segment that contains the Shine-Dalgarno sequence of the ribosome binding site. In the distantly related bacteriophage RB69 there is a remarkable conservation of this hairpin and loop sequence at the ribosome binding site of its DNA polymerase gene. We have constructed phage operator mutants that overproduce gp43 in vivo, yet are unchanged for in vivo replication rates and phage yield. We present data that show that the replicative and autoregulatory functions are mutually exclusive activities of this polymerase, and suggest a model for gp43 synthesis that links autoregulation to replicative demand.     

Recognition of template-primer and gapped DNA substrates by the human DNA polymerase beta

Interactions between human DNA polymerase beta and the template-primer, as well as gapped DNA substrates, have been studied using quantitative fluorescence titration and analytical ultracentrifugation techniques. In solution, human pol beta binds template-primer DNA substrates with a stoichiometry much higher than predicted on the basis of the crystallographic structure of the polymerase-DNA complex. The obtained stoichiometries can be understood in the context of the polymerase affinity for the dsDNA and the two ssDNA binding modes, the (pol beta)(16) and (pol beta)(5) binding modes, which differ by the number of nucleotide residues occluded by the protein in the complex. The analysis of polymerase binding to different template-primer substrates has been performed using the statistical thermodynamic model which accounts for the existence of different ssDNA binding modes and has allowed us to extract intrinsic spectroscopic and binding parameters. The data reveal that the small 8 kDa domain of the enzyme can engage the dsDNA in interactions, downstream from the primer, in both (pol beta)(16) and (pol beta)(5) binding modes. The affinity, as well as the stoichiometry of human pol beta binding to the gapped DNAs is not affected by the decreasing size of the ssDNA gap, indicating that the enzyme recognizes the ssDNA gaps of different sizes with very similar efficiency. On the basis of the obtained results we propose a plausible model for the gapped DNA recognition by human pol beta. The enzyme binds the ss/dsDNA junction of the gap, using its 31 kDa domain, with slight preference over the dsDNA. Binding only to the junction, but not to the dsDNA, induces an allosteric conformational transition of the enzyme and the entire enzyme-DNA complex which results in binding of the 8 kDa domain with the dsDNA. This, in turn, leads to the significant amplification of the enzyme affinity for the gap over the surrounding dsDNA, independent of the gap size. The presence of the 5'-terminal phosphate, downstream from the primer, has little effect on the affinity, but profoundly affects the ssDNA conformation in the complex. The significance of these results for the mechanistic model of the functioning of human pol beta is discussed.     

Promoter search by Escherichia coli RNA polymerase on a circular DNA template

Using the rapid-mixing/photocross-linking technique developed in our laboratory, we have investigated the kinetics of interaction between Escherichia coli RNA polymerase and pAR1319, a recombinant plasmid DNA containing the bacteriophage T7 A2 early promoter. By monitoring the time-dependent density of bound RNA polymerase along the relaxed circular DNA molecule using this technique, we have been able to demonstrate kinetic evidence for linear diffusion of RNA polymerase along DNA in a different system from that previously described (Park, C. S., Hillel, Z., and Wu, C.-W. (1982) J. Biol. Chem. 251, 6950-6956). The nonspecific association rate constant kon was measured to be 7.7 x 10(4) M-1 s-1 at a DNA chain concentration of 22.4 nM. By taking advantage of the fact that rapid mixing displaces bound protein molecules from DNA, but leaves them within the domain of the DNA, the rate of intradomain binding of RNA polymerase to pAR1319 DNA was determined to be 8.2 s-1. Since the plasmid is described by a radius of gyration of 0.22 microns, the intradomain concentration of base pairs could be calculated. Using this concentration (180 microM), the rate constant for intradomain nonspecific association of RNA polymerase to pAR1319 DNA was estimated to be 4.6 x 10(4) M-1 s-1. In addition, a mathematical model has been used to fit the other two important rate constants to the experimental data: koff, which describes the dissociation of RNA polymerase from nonspecific binding sites, and D1, the one-dimensional diffusion coefficient of the enzyme along the DNA molecule. In this model, the circular DNA molecule is described as a ring of interconnected binding sites which together comprise a DNA "domain." RNA polymerase, which enters the domain via three-dimensional diffusion and binds to each site, is allowed to diffuse linearly between adjacent sites and three-dimensionally on and off the DNA molecule. The rate equations for the time-dependent occupancy of each site by RNA polymerase could be written, based on general principles. By solving the resulting family of differential equations, koff and D1 were determined to be 0.3 s-1 and 1.5 x 10(-9) cm2 s-1, respectively.     

Dehydroaltenusin, a mammalian DNA polymerase alpha inhibitor

Dehydroaltenusin was found to be an inhibitor of mammalian DNA polymerase alpha (pol alpha) in vitro. Surprisingly, among the polymerases and DNA metabolic enzymes tested, dehydroaltenusin inhibited only mammalian pol alpha. Dehydroaltenusin did not influence the activities of the other replicative DNA polymerases, such as delta and epsilon; it also showed no effect even on the pol alpha activity from another vertebrate (fish) or plant species. The inhibitory effect of dehydroaltenusin on mammalian pol alpha was dose-dependent, and 50% inhibition was observed at a concentration of 0.5 microm. Dehydroaltenusin-induced inhibition of mammalian pol alpha activity was competitive with the template-primer and non-competitive with the dNTP substrate. BIAcore analysis demonstrated that dehydroaltenusin bound to the core domain of the largest subunit, p180, of mouse pol alpha, which has catalytic activity, but did not bind to the smallest subunit or the DNA primase p46 of mouse pol alpha. These results suggest that the dehydroaltenusin molecule competes with the template-primer molecule on its binding site of the catalytic domain of mammalian pol alpha, binds to the site, and simultaneously disturbs dNTP substrate incorporation into the template-primer.     

Baculovirus expression reconstitutes Drosophila mitochondrial DNA polymerase.

Drosophila mitochondrial DNA polymerase has been reconstituted and purified from baculovirus-infected insect cells. Baculoviruses encoding full-length and mature forms of the catalytic and accessory subunits were generated and used in single and co-infection studies. Recombinant heterodimeric holoenzyme was reconstituted in both the mitochondria and cytoplasm of Sf9 cells and required the mitochondrial presequences in both subunits. The recombinant holoenzyme contains DNA polymerase and 3'-5' exonuclease that are stimulated substantially by both salt and mitochondrial single-stranded DNA-binding protein. Thus, the recombinant enzyme exhibits biochemical properties indistinguishable from those of the native enzyme from Drosophila embryos. Production of the catalytic subunit alone yielded soluble protein with the chromatographic properties of the heterodimeric holoenzyme. However, the purified catalytic core has a 50-fold lower specific activity. This provides evidence of a critical role for the accessory subunit in the catalytic efficiency of Drosophila mitochondrial DNA polymerase.